Three-dimensional omni-directional antenna designs for ultra-wideband applications
The present invention generally relates to the field of microwave antennas, and, more particularly, to a number of three-dimensional designs for the radiation element of an ultra-wideband monopole antenna with a symmetrical omni-directional radiation pattern operated in the frequency range between 3.1 GHz and 10.6 GHz. Said antenna is connected to the analog front-end circuitry of a wireless communication device used for transmitting and/or receiving microwave signals and meets the FCC requirements in terms of antenna gain, radiation pattern, polarization, frequency bandwidth, group delay, and size. It comprises a radiation element consisting of an air- and/or dielectric-filled cavity structure with a base plane and a radiator plane. A metallic ground plane having a relatively high surface impedance to electromagnetic waves within said frequency range, which is printed on a dielectric substrate, serves as a reflector. The monopole antenna further comprises an antenna feeding circuitry used for electronically steering the symmetrical omni-directional radiation pattern and a feeding line connecting the antenna feeding circuitry with the base plane of the radiation element. Thereby, parts of the analog front-end circuitry can optionally be placed within the air-filled part of the radiation element of the antenna. The proposed designs include a radiation element having the form of a truncated right circular cone, rotational-symmetric radiation elements with a convexly- or concavely-shaped 3D surface, respectively, a radiation element in the form of a truncated right regular pyramid with a square base plane, and radiation elements with a combined structure comprising a conical, pyramidal, convexly- or concavely-shaped first part and a closed cylindrical or cuboidal second part whose top plane is arranged on top of the congruent base plane of said first part. Further embodiments include radiation elements with the form of a radially notched cylinder or hemisphere as well as combined structures consisting of at least two convexly-shaped elements or two conical parts, respectively, stacked on top of each other.
The present invention generally relates to the field of microwave antennas, and more particularly, to three-dimensional designs for the radiation element of an ultra-wide-band (UWB) monopole antenna with a symmetrical omni-directional radiation pattern for transmitting and/or receiving microwave signals.
UWB generally covers a frequency range between 3.1 GHz and 10.6 GHz. A FCC definition is given e.g. in IEEE 802.15 the disclosure of which is hereby incorporated by reference. According to the IEEE 802.15 Working Group for Wireless Personal Area Networks (see e.g. http://www.ieee802.org/15/) the 802.15 WPAN™ effort focuses on the development of Personal Area Networks or short distance wireless networks. These WPANs address wireless networking of portable and mobile computing devices such as PCs, Personal Digital Assistants (PDAs), peripherals, cell phones, pagers, and consumer electronics; allowing these devices to communicate and interoperate with one another.
The main issues concerning the design of microwave antennas usable for UWB are
-
- to have the capability of a simple planar feeding and a printed low-cost manufacturing,
- to achieve a significant cost reduction by simultaneously applying the core substrate of the RF front-end chip as a substrate for the antenna, which means that antenna prints could simultaneously be manufactured by using the layout procedure for classic RF front-end chip circuits, and
- to have the capability to cope with symmetrical omni-directional antenna patterns with gains of 0 to 1 dBi (type 1) and/or sector gains of around 6 dBi (type 2).
Recently, since emphasis has been laid on reducing size, providing increased power efficiency and meeting the requirements of the Federal Communications Commission (FCC) for mobile handset emissions, two additional elements of antenna design have risen in importance that must equally be considered along with conventional design parameters: the enhancement of antenna efficiency and control of the Specific Absorption Rate (SAR).
It is well known that the length of a microwave antenna is inversely proportional to the frequency of transmission: The smaller the antenna size, the lower the antenna efficiency and the narrower is the bandwidth. Thus, as new wireless applications move up in frequency, their antennas correspondingly decrease in size. This natural size reduction, however, is no longer sufficient to meet the demands of consumers. For this reason, antennas are more and more becoming customized components, unique to each wireless manufacturer's performance, size and cost requirements. This evolution is being driven by new radio applications and services which call for antennas that are able
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- to achieve a higher gain, thereby allowing a reduction in transmitter battery power and a better reception in “dead spots”,
- to allow multi-band operation by integrating PCS-based applications operating at 1,900 MHz, applications based on GPS and/or wireless data exchange applications into a single antenna,
- to support directional control over handset emissions by allowing more flexible antenna designs which can be used to control the direction of emissions in the vicinity of body tissue and to achieve a better signal reception, and finally
- to provide a wider channel bandwidth in order to satisfy the ever-increasing demands for high data rates.
Usually, microwave antennas are specified according to a set of parameters including operating frequency, gain, voltage standing wave ratio (VSWR), antenna input impedance and bandwidth. If the VSWR is greater than 3, for instance, a matching network has to be placed between the transmitter and its antenna to minimize mismatch loss, although a low VSWR is not a design necessity as long as the antenna is an efficient radiator. Said design is costly and makes an automation of the matching function much slower than designs applying low-power and solid-state tuning elements.
Ultra-wideband (UWB) technology, which was originally developed for ground-penetrating radar (GPR) applications, came into use as a result of researchers' efforts for detecting and locating surface-laid and shallow-buried targets, e.g. anti-personal landmines. With the development of RF electronics the initial desire to discriminate between two closely flying airplanes changed to the quest for constructing a three-dimensional image of a radar target. The potential for direct reduction of the incident pulse duration was soon exhausted and followed by a detailed analysis of target-reflected signals. It became clear that the most important changes in a target response occurred during a transient process with the duration of one or two oscillations. This fact in itself led to the idea of using UWB signals of this duration without energy expenditure for steady oscillation transmission.
Due to the evolution of wireless communications in the area of cellular telephony, wireless local area networks (WLANs) and wireless personal area networks (WPANs), particularly in the frequency range between 0.9 and 5 GHz, higher frequency bands and ultra-wideband wireless communication systems with minimal RF electronics, high data rate performance, low power consumption and a low probability of detection (LPD) signature are urgently needed. Today, UWB system are e.g. used as a wireless RF interface between mobile terminals (cell phones, laptops, PDAs, wireless cameras or MP3 players) with much higher data rates than Bluetooth or IEEE 802.11. A UWB system can further be used as an integrated system for automotive in-car services, e.g. for downloading driving directions from a PDA or laptop for use by a GPS-based on-board navigation system, as an entertainment system or any location-based system, e.g. for downloading audio or video data for passenger entertainment.
Ultra-wideband monopole antennas and modified monopoles are employed in a wide variety of applications today. Traditionally, mobile phones and wireless handsets are equipped with wideband and ultra-wideband monopole antennas. One of the most common λ/4 monopole antennas is the so-called whip antenna, which can operate at a range of frequencies and is capable of dealing with most environmental conditions better than other monopole antennas. However, a monopole antenna also involves a number of drawbacks. Monopole antennas are relatively large in size and protrude from the handset case in an awkward way. The problem with a monopole antenna's obstructive and space-demanding structure complicates any efforts taken to equip a handset with several antennas to enable multi-band operation.
There are a wide variety of methods being investigated to deal with the deficiencies of the common λ/4 monopole antenna, many of these methods being based on microstrip antenna designs. One such promising design is the Inverted-F Antenna (IFA), a distant derivative of the monopole antenna. The IFA utilizes a modified inverted-L low profile structure, which has frequently been used for aerospace applications. The common IFA comprises a rectangular radiation element with an omni-directional radiation pattern and exhibits a reasonably high antenna gain. The bandwidth of the IFA is broad enough for mobile operation, and the antenna is also highly sensitive to both vertically and horizontally polarized radio waves, thus making the IFA ideally suited to mobile applications. Since there is an increasing demand for antennas that can be operated at multiple frequency bands, cellular phone systems nowadays operate at a number of frequency bands (e.g. 900 MHz, 1.8 GHz, and 2.0 GHz).
BRIEF DESCRIPTION OF THE PRESENT STATE OF THE ARTAccording to the state of the art, different approaches have been pursued to meet advanced requirements of designing low-cost solutions for high-performance broadband microwave antennas with a reduced size and a significantly improved performance. These microwave antennas achieve higher gain, make multiple-band operation possible, allow directional control over electromagnetic emissions of mobile handsets, which leads to a higher antenna efficiency, and provide wider bandwidths to satisfy the ever-increasing demands for data rates of mobile applications. Since these requirements involve complex design problems, wireless device manufacturers are realizing that antenna solutions based on conventional technologies are no longer sufficient.
An apparatus for establishing a signal coupling between a signal supply and an UWB antenna comprising a first and a second radiating element for being operated in a frequency band between 2 and 6 GHz is disclosed in WO 02/093690 A1. The signal supply thereby delivers a signal to the antenna at a connection locus including one edge of the first radiating element and one edge of the second radiating element. The apparatus further comprises a first and a second feed structure. Said first feed structure extends a feed distance from the signal supply to said edge of the second radiating element and divides the first radiating element into two regions in spaced relation with the first feed structure to establish a tapered separation distance between the first feed structure and the two regions. Said second feed structure couples the signal supply with the first radiating element. The aforementioned separation distance thereby establishes a signal transmission structure between the two regions and the first feed structure.
The invention described in US 2002/0053994 A1 refers to a planar UWB antenna with an integrated electronic circuitry. The antenna comprises a first balance element which is connected to a terminal at one end. A second balance element is connected to another terminal at another end. Thereby, said second balance element has a shape which mirrors the shape of the first balance element such that there is a symmetry plane where any point on the symmetry plane is equidistant to all mirror points on the first and second balance element. Each of the balance elements is made of an essentially conductive material. A triangular-shaped ground element is situated between the first balance element and the second balance element with an axis of symmetry on the symmetry plane and oriented such that the base of the triangle is towards the terminals. Accordingly, the ground element and each of the balance elements form two tapered gaps which widen and converge at the apex of the ground element as the taper extends outwardly from the terminals. Under this arrangement, sensitive UWB electronics can be housed within the perimeter of the ground element, thereby eliminating transmission line losses and dispersion. A resistive loop connected between the first and second balance element extends the low frequency response and improves the voltage standing wave ratio. A connection of a linear array of elements is disclosed that provides a low-frequency cutoff defined by the array size and limits its radiation pattern to one direction with a radiation angle of maximal 180 degrees in azimuth.
OBJECT OF THE UNDERLYING INVENTIONIn view of the explanations mentioned above, it is the object of the invention to propose a design for an ultra-wideband antenna (frequency range between 3.1 GHz and 10.6 GHz) that fulfill the UWB standard specifications and meet the FCC requirements in terms of antenna gain, radiation pattern, polarization, frequency bandwidth, group delay, and small size.
This object is achieved by means of the features of the independent claims. Advantageous features are defined in the subordinate claims.
SUMMARY OF THE INVENTIONThe present invention is basically dedicated to a number of three-dimensional designs for the radiation element of a monopole antenna with a symmetrical omni-directional radiation pattern for transmitting and/or receiving microwave signals within a predetermined bandwidth of operation, which is connectable e.g. to the analog front-end circuitry of a wireless RF transceiver. Said monopole antenna can be operated in the frequency range between 3.1 and 10.6 GHz. It comprises e.g. an air- and/or dielectric-filled cavity structure with a base plane and a radiator plane serving as a radiation element, which provides a symmetrical omni-directional radiation pattern, a metallic ground plane serving as a reflector with a relatively high surface impedance to electromagnetic waves within a limited frequency range, printed on a dielectric substrate, an antenna feeding circuitry used for electronically steering the symmetrical omni-directional radiation pattern, and a feeding line connecting the antenna feeding circuitry with the base plane of the radiation element. According to the invention, parts of the analog front-end circuitry can optionally be placed within the radiation element of the ultra-wideband monopole antenna.
The proposed designs include a radiation element having the form of a truncated right circular cone, rotational-symmetric radiation elements with a convexly- or concavely-shaped 3D surface, respectively, a radiation element in the form of a truncated right regular pyramid with a square base plane, and radiation elements with a combined structure comprising a conical, pyramidal, convexly- or concavely-shaped first part as well as a closed cylindrical or cuboidal second part whose top plane is arranged above the congruent base plane of the first part. Further designs include radiation elements in the form of a radially notched cylinder or hemisphere and combined structures consisting of convexly-shaped or conical parts, respectively, stacked on top of each other. The monopole antenna has an overall size of less than 1 cm3, which makes it easy to be integrated in any wireless communication device.
BRIEF DESCRIPTION OF THE DRAWINGSFurther advantages and possible applications of the underlying invention result from the subordinate claims as well as from the following description of different embodiments of the invention as depicted in the following drawings. Herein,
In the following, different embodiments of the underlying invention as depicted in
FIGS. 1 to 3l shall be explained in detail. The meaning of the symbols designated with reference numerals in FIGS. 1 to 3l can be taken from an annexed table.
According to a further embodiment of the present invention, the monopole antenna 100 has an unbalanced RF input port, e.g. as disclosed in US 2002/0053994 A1, which provides more flexibility in the implementation of consumer electronic equipment. Moreover, an unbalanced input port is more flexible when connecting the antenna to an RF module via coaxial cable. It further allows a direct connection of the metallic ground plane 204 to the ground of the antenna feeding circuitry 211 and can be used for measurement purposes in which a conventional network analyzer is sufficient, whereas in case of a balanced RF input port a differential-to-single-ended converter (a balun) is required.
As depicted in
According to one embodiment of the present invention, the ultra-wideband monopole antenna is a part of an antenna terminal which is specially designed for being operated in the frequency range between 3.1 and 10.6 GHz. Said antenna provides a symmetrical omni-directional radiation pattern in azimuth plane with 90 degrees in elevation over the entire frequency range. The radiation beam thereby exhibits a linear vertical polarization, linear phase variation Δφ versus frequency ω, which means a constant group delay
over the entire frequency range, as well as a flat amplitude response (around 3 dB) over the entire frequency range. Without using a resistive load, the return loss
RL:=−20·log10|ρ|[dB], (2a)
which is defined over the magnitude of the complex-valued reflection coefficient ρ as the ratio (in dB) of the power incident on the antenna terminal to the power reflected from the antenna terminal, has a value of less than −10 dB in a frequency range between 3.1 GHz and 10.6 GHz, which corresponds to a voltage standing wave ratio
of less than 2. In case a resistive load and/or additional impedance matching circuitries are used, a return loss even better than −10 dB can be achieved.
In the following, different designs of the ultra-wideband monopole antenna 100 according to twelve embodiments 300a-l of the present invention as depicted in
The second 3D surface plot depicted in
The fourth 3D surface plot depicted in
The sixth 3D surface plot depicted in
The eighth 3D surface plot depicted in
Analogously,
The eleventh 3D surface plot depicted in
The twelfth 3D surface plot depicted in
Within the cavity resonator 202a of the radiation element 202, transversal electromagnetic mode (TEM) waves exist together with higher-order modes created at the base plane 202a′ of the radiation element 202. These higher-order modes are the major contribution to the reactive part X(O) of the antenna input impedance Z(ω)=R(ω)+j·X(ω). Reflections of the electromagnetic waves at the base plane 202a′ and standing waves thereby lead to a complex-valued antenna input impedance Z(ω) with a reactive part X(ω)≠0. It can be shown that X(ω) depends on the length of the radiation element and X(ω)=0 can only be achieved for a biconical radiation element 202 with infinite length. By increasing the aperture angle of the radiation element 202, the reactance X(ω) can be hold to a minimum over a wide frequency range. At the same time, the resistive part R(ω) of the antenna input impedance Z(ω) becomes less sensitive to changing angular frequency w or changes in the length.
A still further embodiment of the present invention refers to an RF transceiver of a wireless communications device, wherein a monopole antenna 100 as described above is employed. Furthermore, a further monopole antenna 100′ of the same type as described above can be symmetrically attached to the rear side of the metallic ground plane 204 with respect to the existing monopole antenna 100, thus forming a dipole antenna dimensioned for the Ultra-Wideband frequency range.
Finally, the invention refers to an electronic device having a wireless interface which comprises an RF transceiver as described above.
Claims
1. A monopole antenna for microwave signals, attachable to the analog front-end circuitry of a wireless communication device, wherein said antenna is dimensioned for the Ultra-Wideband frequency range and comprises
- a three-dimensional cavity structure with radiating elements with a base plane serving as
- a radiation element,
- a metallic ground plane,
- an antenna feeding circuitry, and
- a feeding line connecting the antenna feeding circuitry with the base plane of the radiation element.
2. A monopole antenna according to claim 1,
- comprising
- a radiator plane serving also as a radiation element.
3. A monopole antenna according to claim 1,
- characterized in that
- at least parts of the analog front-end circuitry are placed within the radiation element of the ultra-wideband monopole antenna.
4. A monopole antenna according to claim 3,
- characterized in that
- the analog front-end circuitry placed within the radiation element comprises at least one of band-select filtering means, amplification means and band pass filtering means.
5. A monopole antenna according to claim 1,
- characterized in that
- the radiation element has a rotational-symmetric form with a circular cross section and a conical structure.
6. A monopole antenna according to claim 1,
- characterized in that
- the radiation element comprises a first part having a rotational-symmetric form with a circular cross section, a conical structure and a second part having the form of a closed right circular cylinder with a circular top plane congruent to the circular base plane of the conical first part, wherein the circular top plane of the cylindrical second part is coaxially arranged above the congruent circular base plane of said first part.
7. A monopole antenna according to claim 1,
- characterized in that
- the radiation element has a rotational-symmetric form with a circular cross section, a conical structure and a concave 3D surface.
8. A monopole antenna according to claim 1,
- characterized in that
- the radiation element comprises a first part having a rotational-symmetric form with a circular cross section, a conical structure, a concave 3D surface and a second part having the form of a closed right circular cylinder with a circular top plane congruent to the circular base plane of the conical first part, wherein the circular top plane of the cylindrical second part is coaxially arranged above the congruent circular base plane of the concavely-shaped first part.
9. A monopole antenna according to claim 1,
- characterized in that
- the radiation element has a rotational-symmetric form with a circular cross section, a conical structure and a convex 3D surface.
10. A monopole antenna according to claim 1,
- characterized in that
- the radiation element comprises a first part having a rotational-symmetric form with a circular cross section, a conical structure, a convex 3D surface and a second part having the form of a closed right circular cylinder with a circular top plane congruent to the circular base plane of the conical first part, wherein the top plane of the cylindrical second part is coaxially arranged above the congruent circular base plane of the convexly-shaped first part.
11. A monopole antenna according to claim 1,
- characterized in that
- the radiation element has the form of a truncated right regular pyramid with a square base plane.
12. A monopole antenna according to claim 1,
- characterized in that
- the radiation element comprises a first part in form of a truncated right square pyramid and a second part having the form of a closed right rectangular parallelepiped with a square top plane congruent to the square base plane of the pyramidal first part, wherein the square top plane of the cuboidal second part is arranged above the congruent square base plane of the pyramidal first part.
13. A monopole antenna according to claims 1,
- characterized in that
- the radiation element has the form of a right circular cylinder with four V-shaped radial notches running in longitudinal direction, equally spaced in azimuth around the circumference of the cylinder, which leads to a cross section in the form of two perpendicular crossing elliptical structure.
14. A monopole antenna according to claim 1,
- characterized in that
- the radiation element has the form of a hemisphere with four V-shaped radial notches running in longitudinal direction, equally spaced in azimuth around the circumference of the hemisphere, which leads to a cross section in the form of two perpendicularly crossing elliptical structure
15. A monopole antenna according to claim 1,
- characterized in that
- the radiation element comprises at least two parts of the same or different height, each having a rotational-symmetric form with a circular cross section, a conical structure and a convex 3D surface, wherein each part of a first group of said parts has a circular top plane congruent to the circular base plane of a part of a second group of said parts, respectively, said parts being stacked on top of each other in the order of the length of their radii, wherein the circular top planes of the parts from said first group are coaxially arranged above the congruent circular base planes of the adjacent next smaller parts from said second group, respectively.
16. A monopole antenna according to claim 1,
- characterized in that
- the radiation element comprises a first part having the form of a truncated right circular cone with a circular base plane and a second part having the form of a closed right circular cone with a smaller height and a bigger aperture angle, wherein the cone top of the second part is coaxially attached to the center of the circular base plane of the first part.
17. A monopole antenna according to claim 1,
- characterized in that
- the radiation beam exhibits a linear vertical polarization.
18. A monopole antenna according to claim 1,
- characterized in that
- the feeding line connecting the antenna feeding circuitry with the base plane of the radiation element is realized as a coaxial cable.
19. A monopole antenna according to claim 1,
- characterized in that
- the feeding line connecting the antenna feeding circuitry with the base plane of the radiation element is realized as a microstrip line.
20. A monopole antenna according to claim 19,
- characterized in that
- the radiation beam exhibits a flat amplitude response around 3 dB over the entire frequency range.
21. A monopole antenna according to claim 19,
- characterized by
- a symmetrical omni-directional radiation pattern in azimuth plane with 160 degrees in elevation over the entire frequency range.
22. A monopole antenna according to claim 21,
- characterized in that
- the symmetrical omni-directional radiation pattern approximately exhibits linear phase variation versus frequency.
23. A monopole antenna according to claim 19,
- characterized by
- a return loss of less than −10 dB in a frequency range between 3.1 and 10.6 GHz, which corresponds to a voltage standing wave ratio of less than 2.
24. A monopole antenna according to claim 19,
- characterized by
- a return loss even better than −10 dB in a frequency range between 3.1 and 10.6 GHz when using a resistive load and/or additional impedance matching circuitries.
25. A monopole antenna according to claim 1,
- characterized in that
- the radiation element has an overall size of less than 1 cm3.
26. An RF transceiver of a wireless communications device,
- characterized by
- a monopole antenna according to claim 1.
27. An RF transceiver according to claim 26,
- characterized by
- a further monopole antenna with respect to the existing monopole antenna symmetrically attached to the rear side of the metallic ground plane, thus forming a dipole antenna dimensioned for the Ultra-Wideband frequency range.
28. An electronic device having a wireless interface comprising an RF transceiver according to claim 26.
Type: Application
Filed: Dec 9, 2004
Publication Date: Jul 21, 2005
Patent Grant number: 7286094
Inventors: Mohamed Ratni (Esslingen), Dragan Krupezevic (Stuttgart)
Application Number: 11/007,949